Two suppressor loci for gene 49 mutations of bacteriophage T4. II. DNA and capsid maturation

Double-strand break repair and recombination-dependent replication of DNA in bacteriophage T4 in the absence of UvsX recombinase: replicative resolution pathway

The effects of mutations in bacteriophage T4 genes uvsX and 49 on the double-strand break (DSB)-promoted recombination were studied in crosses, in which DSBs were induced site-specifically within the rIIB gene by SegC endonuclease in the DNA of only one of the parents. Frequency of rII+ recombinants was measured in two-factor crosses of the type i×ets1 and in three-factor crosses of the type i×ets1 a6, where ets1 is an insertion in the rIIB gene carrying the cleavage site for SegC; i's are rIIB or rIIA point mutations located at various distances (12-2040 bp) from the ets1 site, and a6 is rIIA point mutation located at 2040 bp from ets1. The frequency/distance relationships were obtained in crosses of the wild-type phage and of the amber mutant S17 (gene uvsX) and the double mutant S17 E727 (genes uvsX and 49). These data provide information about the frequency and distance distribution of the single-exchange (splices) and double-exchange (patches) events. The extended variant of the splice/patch coupling (SPC) model of recombination, which includes transition to the replication resolution (RR) alternative is substantiated and used for interpretation of the frequency/distance relationships. We conclude that the uvsX mutant executes recombination-dependent replication but does it by a qualitatively different way. In the absence of UvsX function, the DSB repair runs largely through the RR subpathway because of inability of the mutant to form a Holliday junction. In the two-factor crosses, the double uvsX 49- is recombinationally more proficient than the single uvsX mutant (partial suppression of the uvsX deficiency), while the patch-related double exchanges are virtually eliminated in this background.

UvsY protein of bacteriophage T4 is an accessory protein for in vitro catalysis of strand exchange

The uvsX and uvsY genes are essential to genetic recombination, recombination-dependent DNA synthesis and to the repair of DNA damage in bacteriophage T4. Purified UvsX protein has been shown to catalyze strand exchange and D-loop formation in vitro, but the role of UvsY protein has been unclear. We report that UvsY protein enhances strand exchange by UvsX protein by interacting specifically with UvsX protein: gene 32 protein (gp32) is not necessary for this effect and UvsY protein has no similar effect on the RecA protein of E. coli. UvsY protein, like UvsX protein, protects single-stranded DNA from digestion by nucleases, but, unlike UvsX protein, shows no ability to protect double-stranded DNA. UvsY protein enhances the rate of single-stranded-DNA-dependent ATP hydrolysis by UvsX protein, particularly in the presence of gp32 or high concentrations of salt, factors that otherwise reduce the ATPase activity of UvsX protein. The enhancement of ATP hydrolysis by UvsY protein is shown to result from the ability of UvsY protein to increase the affinity of UvsX protein for single-stranded DNA.

Structural features of very fast sedimenting DNA formed by gene 49 defective T4

Very fast sedimenting DNA (VFS DNA) of T4 phage, which is formed by infection with a mutant in gene 49, was examined by electron microscopy after mild treatment with DNase I. It showed Y-shaped, branched strands in addition to linear strands. Each branch contained a single-stranded interruption about 60 nucleotides long at its proximal end. The average number of branches per T4 DNA unit was close to the average number of sites susceptible to gene 49 nuclease. Both numbers were consistently changed by the addition of a secondary mutation in a gene involving recombination.

Genetic control of formation of very fast sedimenting DNA of bacteriophage T4

Formation of very fast sedimenting DNA (VFS-DNA) in cells of Escherichia coli infected with phage T4 carrying a defect in gene 49 was differentially affected by a secondary mutation in gene 30 or 46; a mutation of gene 46 markedly reduced formation of VFS-DNA, whereas that of gene 30 did not.

Suppression of gene 49 mutations of bacteriophage T4 by a second mutation in gene X: structure of pseudorevertant DNA

Mutations in gene 49 of bacteriophage T4 were suppressed by a second mutation in gene X. Mapping studies located gene X between genes 41 and 42. Complementation results indicated that mutations in FdsA gene (a suppressor of gene 49 mutants) were in gene X. The intracellular pseudorevertant DNA was examined for unusual properties which could explain its successful encapsidation. After the in vivo inactivation of a temperature-sensitive gene 32 (DNA unwinding) protein, the intracellular pseudorevertant DNA was converted into DNA pieces of approximately genome size. A similar conversion was observed after in vitro digestion of pseudorevertant DNA with single-strand-specific S1 endonuclease. Appreciable quantities of oligomeric intermediates were not produced during this conversion process. These data indicate that pseudorevertant DNA contains sizable single-stranded gaps and has a conformation similar to that of wild-type DNA. The results further suggest that the suppression of gene 49 mutant abnormal DNA phenotype and the encapsidation defect by a second mutation in gene X is associated with the formation of sizable single-stranded gaps. These studies raise the possibility that single-stranded gaps may be involved directly in the DNA encapsidation process, or may act indirectly as a consequence of their effect on the organization of intracellular DNA.